Imaging device, imaging system, and imaging method

ABSTRACT

An imaging apparatus of the present invention includes: a lens optical system including a lens and a stop; an imaging device including at least a plurality of first pixels and a plurality of second pixels on which light having passed through the lens optical system is incident; and an arrayed optical device arranged between the lens optical system and the imaging device, wherein: the lens optical system includes, in a plane vertical to an optical axis, a first optical area that transmits therethrough light of a first wavelength band and a second optical area that transmits therethrough light of a second wavelength band different from the first wavelength band; and the arrayed optical device makes light having passed through the first optical area incident on the plurality of first pixels and light having passed through the second optical area incident on the plurality of second pixels.

TECHNICAL FIELD

The present invention relates to an imaging apparatus such as a camera.

BACKGROUND ART

A color filter using an organic material such as a pigment or a dye istypically formed on each pixel of a solid-state imaging device for colorimaging. Since such a color filter allows infrared light to passtherethrough, an infrared cut filter is typically arranged along theoptical path upstream of the solid-state imaging device in order toobtain a desirable color image with an imaging apparatus. Therefore,with an imaging apparatus using a single imaging device, it is difficultto simultaneously obtain both image information of visible light andthat of infrared light. A color filter using an organic material has awide wavelength band and the wavelength bands of blue, green and redoverlap with one another over relatively wide wavelength bands, forexample, thereby deteriorating the color reproducibility.

In view of this, in order to solve these problems, techniques have beendisclosed which relate to a solid-state imaging device in which a colorfilter of a dielectric multi-layer film is formed (Patent Documents 1and 2).

With a color filter using an organic material, it is difficult to formnarrow-band spectral characteristics, and it is difficult to capture animage by extracting color information of narrow wavelength bands.

In view of this, a technique has been disclosed for obtaining an imageby successively turning on white light and predetermined narrow-bandlight in order to obtain color information of narrow bands (PatentDocument 3).

CITATION LIST Patent Literature

Patent Document No. 1: Japanese Laid-Open Patent Publication No.2010-212306

Patent Document No. 2: Japanese Laid-Open Patent Publication No.2006-190958

Patent Document No. 3: Japanese Patent No. 4253550

SUMMARY OF INVENTION Technical Problem

With Documents 1 and 2, since a step of forming a dielectric multi-layerfilm for each of minute pixels is needed, the solid-state imaging devicewill be expensive. Moreover, the formation is difficult with very minutepixel sizes.

Document 3 is a scheme in which an image is captured in a time divisionmethod by successively turning on white light source and predeterminednarrow-band light source. Therefore, when capturing an image of a movingobject, a color shift occurs due to time difference.

Since the spectral characteristics of conventional color imaging devicesare typically standardized for each model in view of the productivity,it is difficult for imaging apparatus manufacturers, who buy them, toarbitrarily specify the spectral characteristics.

The present invention has been made in order to solve the problems setforth above, and a primary object thereof is to provide an imagingapparatus and an imaging method, with which it is possible to obtain anymultispectral image through a single imaging operation using a singleimaging optical system. A multispectral image refers to an image havingspectral information for each pixel.

Solution to Problem

An imaging apparatus of the present invention includes: a lens opticalsystem including a lens and a stop; an imaging device including at leasta plurality of first pixels and a plurality of second pixels on whichlight having passed through the lens optical system is incident; and anarrayed optical device arranged between the lens optical system and theimaging device, wherein the lens optical system further includes aplurality of optical areas in a plane vertical to an optical axis; theplurality of optical areas include a first optical area that transmitstherethrough light of a first wavelength band, and a second optical areathat transmits therethrough light of a second wavelength band differentfrom the first wavelength band; and the arrayed optical device makeslight having passed through the first optical area incident on theplurality of first pixels and light having passed through the secondoptical area incident on the plurality of second pixels.

An imaging system of the present invention includes: an imagingapparatus of the present invention; and a signal processing device forgenerating first image information corresponding to the first wavelengthband from pixel values obtained from the plurality of first pixels ofthe imaging apparatus, and generating second image informationcorresponding to the second wavelength band from pixel values obtainedfrom the plurality of second pixels.

An imaging method of the present invention uses an imaging apparatusincluding: a lens optical system including at least a first optical areathat transmits therethrough light of a first wavelength band, and asecond optical area that transmits therethrough light of a secondwavelength band different from the first wavelength band; an imagingdevice including at least a plurality of first pixels and a plurality ofsecond pixels on which light having passed through the lens opticalsystem is incident; and an arrayed optical device arranged between thelens optical system and the imaging device, wherein: the arrayed opticaldevice makes light having passed through the first optical area incidenton the plurality of first pixels and light having passed through thesecond optical area incident on the plurality of second pixels; and afirst image corresponding to the first wavelength band is generated frompixel values obtained from the plurality of first pixels, and secondimage information corresponding to the second wavelength band isgenerated from pixel values obtained from the plurality of secondpixels.

Advantageous Effects of Invention

According to the present invention, it is possible to obtain anymultispectral image through a single imaging operation using a singleimaging system. According to the present invention, there is no need toprovide a dielectric multi-layer film for each pixel. When a motionvideo is taken using the imaging apparatus of the present invention, noimage shift will occur between a plurality of images even if theposition of the object changes over time.

BRIEF DESCRIPTION OF DRAWINGS

[FIG. 1] A schematic diagram showing Embodiment 1 of an imagingapparatus A of the present invention.

[FIG. 2] A front view of an optical device L1 in Embodiment 1 of thepresent invention as seen from the object side.

[FIG. 3] A perspective view of an arrayed optical device K in Embodiment1 of the present invention.

[FIG. 4] (a) is an enlarged view of the arrayed optical device K and animaging device N of Embodiment 1 shown in FIG. 1, and (b) is a diagramshowing the positional relationship between the arrayed optical device Kand pixels of the imaging device N.

[FIG. 5] A schematic diagram showing Embodiment 2 of the imagingapparatus A of the present invention.

[FIG. 6] A front view of the optical device L1 in Embodiment 2 of thepresent invention as seen from the object side.

[FIG. 7] (a) is an enlarged view of the arrayed optical device K and theimaging device N of Embodiment 2 shown in FIG. 5, and (b) is a diagramshowing the positional relationship between the arrayed optical device Kand pixels of the imaging device N.

[FIG. 8] A front view of the optical device L1 in Embodiment 3 of thepresent invention as seen from the object side.

[FIG. 9] A perspective view of the arrayed optical device K inEmbodiment 3 of the present invention.

[FIG. 10] (a) is an enlarged view of the arrayed optical device K andthe imaging device N of Embodiment 3, and (b) is a diagram showing thepositional relationship between the arrayed optical device K and pixelsof the imaging device N.

[FIG. 11] (a) A front view of the optical device L1 in Embodiment 4 ofthe present invention as seen from the object side, and (b) is a diagramshowing the positional relationship between the arrayed optical device Kand pixels of the imaging device N.

[FIG. 12] Ray diagrams for different object distances in Embodiment 1 ofthe present invention, and diagrams illustrating point images andchanges in centroids thereof.

[FIG. 13] Diagrams illustrating point images and centroids thereof fordifferent object distances in Embodiment 4 of the present invention.

[FIG. 14] (a) and (b) are schematic diagrams showing an optical systemand an imaging section in Embodiment 5 of the present invention.

[FIG. 15] (a) and (b) are perspective views showing the optical deviceL1 in Embodiment 5 of the present invention.

[FIG. 16] (a), (b) and (c) are front views of a stop S in Embodiment 5of the present invention as seen from the object side. [FIG. 17] (a) and(b) are schematic diagrams showing an optical system and an imagingsection in Embodiment 5 of the present invention.

[FIG. 18] A perspective view of the optical device L1 in Embodiment 5 ofthe present invention.

[FIG. 19] (a), (b) and (c) are perspective views of the optical deviceL1 in Embodiment 6 of the present invention.

[FIG. 20] (a), (b) and (c) are front views of the stop S in Embodiment 6of the present invention as seen from the object side.

[FIG. 21] (a), (b) and (c) are perspective views of the optical deviceL1 in Embodiment 7 of the present invention.

[FIG. 22] (a), (b) and (c) are front views of the stop S in Embodiment 7of the present invention as seen from the object side.

[FIG. 23] (a) and (b) are enlarged views of the arrayed optical device Kand the imaging device N in Embodiment 8 of the present invention.

[FIG. 24] (a) and (b) are enlarged views of the arrayed optical device Kand the imaging device N in other embodiments of the present invention.

[FIG. 25] (a1) and (b1) are perspective views of the arrayed opticaldevice K in other embodiments of the present invention, (a2) and (b2)are diagrams showing contour lines of optical elements, and (a3) and(b3) are diagrams showing the results of ray tracking simulations.

DESCRIPTION OF EMBODIMENTS

Embodiments of the imaging apparatus of the present invention will nowbe described with reference to the drawings.

Embodiment 1

FIG. 1 is a schematic diagram showing an imaging apparatus A ofEmbodiment 1. The imaging apparatus A of the present embodiment includesa lens optical system L whose optical axis is V, an arrayed opticaldevice K arranged in the vicinity of the focal point of the lens opticalsystem L, an imaging device N, and a signal processing section C.

The lens optical system L includes a stop S on which light from anobject (not shown) is incident, an optical device L1 on which lighthaving passed through the stop S is incident, and a lens L2 on whichlight having passed through the optical device L1 is incident.

The lens L2 may be formed by a single lens or a plurality of lenses.FIG. 1 shows a single-lens configuration.

The optical device L1 is arranged in the vicinity of the stop.

The optical device L1 has a first optical area D1 that transmitstherethrough light of a first wavelength band, and a second optical areaD2 that transmits therethrough light of a second wavelength band. Thefirst wavelength band and the second wavelength band are different fromeach other.

The “wavelength band”, as in the “first wavelength band” and the “secondwavelength band”, is for example a continuous band that accounts for 50%or more of the total amount of light passing through the area, and anywavelength 95% or more of which is cut off passing through the area isnot included in the “wavelength band”.

Two wavelength bands being different from each other means that at leastone of the wavelength bands includes a band that is not included in theother wavelength band. Therefore, the wavelength bands may partiallyoverlap each other.

A configuration where different wavelength bands are transmitted isrealized by a configuration where a filter using an organic material ora dielectric multi-layer film is formed on one surface of the opticaldevice L1 that is closer to the stop S, a configuration in which anabsorption-type filter is formed, or a configuration in which each areaof the optical device L1 is colored by a dye-type filter. Such colorfilters may be formed on a single flat plate or may be formed on aplurality of flat plates separated from one another for different areas.

In the present embodiment, light having passed through the two opticalareas D1 and D2 are incident on the arrayed optical device K afterpassing through the lens L2. The arrayed optical device K makes lighthaving passed through the optical area D1 incident on pixels P1 of theimaging device N, and makes light having passed through the optical areaD2 incident on pixels P2 of the imaging device N. The signal processingsection C generates image information corresponding to the firstwavelength band from pixel values obtained on the pixels P1, andgenerates image information corresponding to the second wavelength bandfrom pixel values obtained on the pixels P2, to output the imageinformation.

In FIG. 1, a light beam B1 is a light beam passing through the opticalarea D1 on the optical device L1, and a light beam B2 is a light beampassing through the optical area D2 on the optical device L1. The lightbeams B1 and B2 pass through the stop S, the optical device L1, the lensL2 and the arrayed optical device K in this order to arrive at animaging surface Ni on the imaging device N.

FIG. 2 is a front view of the optical device L1 as seen from the objectside. The optical areas D1 and D2 of the optical device L1 are formed bytwo-fold division in the up-down direction in a plane vertical to theoptical axis V with the optical axis V being the center of the boundary.In FIG. 2, the broken line s represents the position of the stop S.

FIG. 3 is a perspective view of the arrayed optical device K. Aplurality of optical elements M1 elongated in the horizontal directionare arranged in the vertical direction on one surface of the arrayedoptical device K that is closer to the imaging device N. The crosssection (in the vertical direction) of each optical element M1 has acurved shape protruding toward the imaging device N. Thus, the arrayedoptical device K has a lenticular lens configuration.

As shown in FIG. 1, the arrayed optical device K is arranged in thevicinity of the focal point of the lens optical system L, and isarranged at a position at a predetermined distance from the imagingsurface Ni.

FIG. 4( a) is an enlarged view of the arrayed optical device K and theimaging device N shown in FIG. 1, and FIG. 4( b) is a diagram showingthe positional relationship between the arrayed optical device K andpixels on the imaging device N. The arrayed optical device K is arrangedso that the surface on which the optical elements M1 are formed facesthe imaging surface Ni. The pixels P are arranged in a matrix pattern onthe imaging surface Ni. The pixels P can be grouped into pixels P1 andpixels P2.

The pixels P1 and the pixels P2 are arranged in rows in the horizontaldirection (row direction). In the vertical direction (column direction),the pixels P1 and P2 are arranged alternating with each other. Thearrayed optical device K is arranged so that each optical element M1thereof corresponds to two rows of pixels including one row or pixels P1and one row of pixels P2 on the imaging surface Ni. Microlenses Ms areprovided on the imaging surface Ni so as to cover the surface of thepixels P1 and P2.

The arrayed optical device K is designed so that the majority of thelight beam (the light beam B1 represented by solid lines in FIG. 1)having passed through the optical area D1 on the optical device L1(shown in FIG. 1 and FIG. 2) arrives at the pixels P1 on the imagingsurface Ni, and the majority of the light beam (the light beam B2represented by broken lines in FIG. 1) having passed through the opticalarea D2 arrives at the pixels P2 on the imaging surface Ni.Specifically, the configuration described above is realized byappropriately setting parameters such as the refractive index of thearrayed optical device K, the distance from the imaging surface Ni, andthe radius of curvature at the surface of the optical element M1.

Where the imaging optical system is an image-side non-telecentricoptical system, the angle of a light beam at the focal point isdetermined by the position of the light beam passing through the stopand the angle thereof with respect to the optical axis. The arrayedoptical device has a function of differentiating the exit directiondepending on the incident angle of the light beam. Therefore, byarranging the optical areas D1 and D2 in the vicinity of the stop andarranging the arrayed optical device K in the vicinity of the focalpoint as described above, the light beams B1 and B2 having passedthrough the respective optical areas can be separately guided to thepixels P1 and P2, respectively. If the position where the optical areasD1 and D2 are arranged is significantly away from the position of thestop, light having passed through the optical area D1 and light havingpassed through the optical area D2 cannot be separated to the pixels P1and the pixels P2, respectively, resulting in a large amount ofcrosstalk. Where the imaging optical system is an image-side telecentricoptical system, since light beams passing through the stop are parallel,the angle of a light beam at the focal point is uniquely determined bythe position of the light beam passing through the stop.

With such a configuration, the pixels P1 and the pixels P2 generateimage information corresponding to light of different wavelength bandsfrom each other. That is, the imaging apparatus A is capable ofobtaining a plurality of image information formed by light of differentwavelength bands from each other through a single imaging operationusing a single imaging optical system.

Specific examples of the first wavelength band and the second wavelengthband will be shown.

In one example, the first optical area D1 is an optical filter havingcharacteristics such that visible light is transmitted therethrough aslight of the first wavelength band while near infrared light issubstantially blocked. The second optical area D2 is an optical filterhaving characteristics such that visible light is substantially blockedwhile near infrared light is transmitted therethrough as light of thesecond wavelength band. Thus, it is possible to realize an imagingapparatus for day and night use or an imaging apparatus for biometricauthentication. With such an imaging apparatus, when obtaining an imageof near infrared light, it is preferred to provide a light source havingspectral radiation characteristics including the band of near infraredlight.

In another example, the first optical area D1 is an optical filterhaving characteristics such that visible light is transmittedtherethrough as light of the first wavelength band while nearultraviolet light is substantially blocked. The second optical area D2is an optical filter having characteristics such that visible light issubstantially blocked while near ultraviolet light is transmittedtherethrough as light of the second wavelength band. Thus, it ispossible to realize an imaging apparatus for visualizing conditions ofthe skin such as blotches due to near ultraviolet rays. With such animaging apparatus, when obtaining an image of near ultraviolet light, itis preferred to provide a light source having spectral radiationcharacteristics including the band of near ultraviolet light.

In another example, the first optical area D1 is an optical filter thattransmits therethrough light of a predetermined wavelength band width,and the second optical area D2 is an optical filter that transmitstherethrough light of a narrower band width than the predeterminedwavelength band width. That is, the width of the first wavelength bandis made narrower than the width of the second wavelength band. Thus, itis possible to realize an imaging apparatus for endoscope or capsuleendoscope applications with which it is possible to observe lesions witha narrow band. In this example, the second wavelength band may or maynot be included in the first wavelength band. With such an imagingapparatus, it is preferred to provide one type of a light source havingspectral radiation characteristics including the first and secondwavelength bands, or a plurality of types of light sources havingspectral radiation characteristics corresponding respectively to thefirst and second wavelength bands. In such an application, it ispossible to easily distinguish a lesion by displaying on a monitor theimage obtained with a wide band and the image obtained with a narrowband in different colors from each other.

In the present embodiment, the pixel value is missing for every otherpixel in the y direction. Therefore, the pixel value of the pixel forwhich it is missing may be generated by interpolation with pixel valuesof pixels adjacent thereto in the y direction, or pixel values in the xdirection may be added together in groups of two pixels.

A configuration may be used where the aspect ratio between the xdirection and the y direction of each pixel of the imaging device is2:1. With such a configuration, the interpolation process or theaddition process as described above will be unnecessary.

Embodiment 2

Embodiment 2 is different from Embodiment 1 in that the area of theoptical device L1 is divided in three. Herein, what is substantially thesame as Embodiment 1 will not be described in detail.

FIG. 5 is a schematic diagram showing the imaging apparatus A ofEmbodiment 2.

In FIG. 5, the light beam B1 is a light beam passing through the opticalarea D1 on the optical device L1, the light beam B2 is a light beampassing through the optical area D2 on the optical device L1, and alight beam B3 is a light beam passing through the optical area D3 on theoptical device L1. The light beams B1, B2 and B3 pass through the stopS, the optical device L1, the lens L2 and the arrayed optical device Kin this order to arrive at the imaging surface Ni (shown in FIG. 7,etc.) on the imaging device N.

FIG. 6 is a front view of the optical device L1 as seen from the objectside, and the optical areas D1, D2 and D3 are formed by three-folddivision in the up-down direction in a plane vertical to the opticalaxis V. The wavelength bands of light passing through different opticalareas are different from each other.

FIG. 7( a) is an enlarged view of the arrayed optical device K and theimaging device N shown in FIG. 5, and FIG. 7( b) is a diagram showingthe positional relationship between the arrayed optical device K andpixels on the imaging device N. The arrayed optical device K is arrangedso that the surface on which the optical elements M1 are formed facesthe imaging surface Ni. The pixels P are arranged in a matrix pattern onthe imaging surface Ni. The pixels P can be grouped into pixels P1,pixels P2, and pixels P3.

The pixels P1, the pixels P2 and the pixels P3 are arranged in rows inthe horizontal direction (row direction). In the vertical direction(column direction), the pixels P1, P2 and P3 are arranged alternatingwith one another. The arrayed optical device K is arranged so that eachoptical element M1 thereof corresponds to three rows of pixels includingone row of pixels P1, one row of pixels P2 and one row of pixels P3 onthe imaging surface Ni. Microlenses Ms are provided on the imagingsurface Ni so as to cover the surface of the pixels P1, P2 and P3.

The arrayed optical device K is designed so that the majority of thelight beam B1 (the light beam B1 represented by dotted lines in FIG. 5)having passed through the optical area D1 on the optical device L1(shown in FIG. 5 and FIG. 6) arrives at the pixels P1 on the imagingsurface Ni, the majority of the light beam (the light beam B2represented by solid lines in FIG. 5) having passed through the opticalarea D2 arrives at the pixels P2 on the imaging surface Ni, and themajority of the light beam (the light beam B3 represented by brokenlines in FIG. 5) having passed through the optical area D3 arrives atthe pixels P3 on the imaging surface Ni. Specifically, the configurationdescribed above is realized by appropriately setting parameters such asthe refractive index of the arrayed optical device K, the distance fromthe imaging surface Ni, and the radius of curvature at the surface ofthe optical element M1.

With such a configuration, the pixels P1, the pixels P2 and the pixelsP3 generate image information corresponding to light of differentwavelength bands from each other. That is, the imaging apparatus A iscapable of obtaining a plurality of image information formed by light ofdifferent wavelength bands from each other through a single imagingoperation using a single imaging optical system.

While Embodiment 1 is a structure with which images of two differentwavelength bands are obtained simultaneously, Embodiment 2 is capable ofsimultaneously obtaining images of three different wavelength bands.

Specific examples of the three different wavelength bands will be shown.

In one example, the first optical area D1 is a blue color filter thattransmits therethrough light of the blue band while substantiallyblocking colors of non-blue bands. The second optical area D2 is a greencolor filter that transmits therethrough light of the green band whilesubstantially blocking colors of non-green bands. The third optical areaD3 is a red color filter that transmits therethrough light of the redband while substantially blocking colors of non-red bands. Thus, it ispossible to realize an imaging apparatus capable of obtaining afull-color image using a monochrome imaging device. The filters are notlimited to filters of primary colors as described above, but may befilers of complementary colors (cyan, magenta, yellow). By using adielectric multi-layer film as the color filters described above, it ispossible to obtain an image with a better color reproducibility thanwith organic filters.

In the present embodiment, the pixel value is missing for every thirdpixel in the y direction. The pixel value of the pixel for which it ismissing may be generated by interpolation with pixel values of pixelsadjacent thereto in the y direction, or pixel values in the x directionmay be added together in groups of three pixels.

A configuration may be used where the aspect ratio between the xdirection and the y direction of each pixel of the imaging device is3:1. With such a configuration, the interpolation process or theaddition process as described above will be unnecessary.

Embodiment 3

Embodiment 3 is different from Embodiment 1 in that the area of theoptical device L1 of FIG. 1 is divided in four, and that the arrayedoptical device is switched from a lenticular to a microlens. Herein,what is substantially the same as Embodiment 1 will not be described indetail.

FIG. 8 is a front view of the optical device L1 as seen from the objectside, and the optical areas D1, D2, D3 and D4 are formed by four-folddivision in the up-down direction and the left-right direction in aplane vertical to the optical axis V with the optical axis V being thecenter of the boundary. The wavelength bands of light passing throughdifferent optical areas are different from each other.

FIG. 9 is a perspective view of the arrayed optical device K. Opticalelements M2 are arranged in a lattice pattern on one surface of thearrayed optical device K that is closer to the imaging device N. Thecross sections (the cross section in the vertical direction and thecross section in the horizontal direction) of each optical element M2has a curved shape, and each optical element M2 is protruding toward theimaging device N. Thus, the optical elements M2 are microlenses, and thearrayed optical device K is a microlens array.

FIG. 10( a) is an enlarged view of the arrayed optical device K and theimaging device N, and FIG. 10( b) is a diagram showing the positionalrelationship between the arrayed optical device K and pixels on theimaging device N. The arrayed optical device K is arranged so that thesurface on which the optical elements M2 are formed faces the imagingsurface Ni. The pixels P are arranged in a matrix pattern on the imagingsurface Ni. The pixels P can be grouped into pixels P1, pixels P2,pixels P3 and pixels P4.

As in Embodiment 1, the arrayed optical device K is arranged in thevicinity of the focal point of the lens optical system L, and isarranged at a position at a predetermined distance from the imagingsurface Ni. Microlenses Ms are provided on the imaging surface Ni so asto cover the surface of the pixels P1, P2, P3 and P4.

The arrayed optical device K is arranged so that the surface on whichthe optical elements M2 are formed faces the imaging surface Ni. Thearrayed optical device K is arranged so that each optical element M2thereof corresponds to two rows and two columns, i.e., four, of pixelsP1-P4 on the imaging surface Ni.

The arrayed optical device K is designed so that the majority of thelight beam having passed through the optical areas D1, D2, D3 and D4 onthe optical device L1 arrive at the pixel P1, the pixel P2, the pixel P3and the pixel P4, respectively, on the imaging surface Ni. Specifically,the configuration described above is realized by appropriately settingparameters such as the refractive index of the arrayed optical device K,the distance from the imaging surface Ni, and the radius of curvature atthe surface of the optical element M1.

With such a configuration, the pixels P1, the pixels P2, the pixels P3and the pixels P4 generate image information corresponding to light ofdifferent wavelength bands from each other. That is, the imagingapparatus A is capable of obtaining a plurality of image informationformed by light of different wavelength bands through a single imagingoperation using a single imaging optical system.

While Embodiment 1 and Embodiment 2 are structures with which images oftwo and three wavelength bands, respectively, are obtainedsimultaneously, Embodiment 3 is capable of simultaneously obtainingimages of four different wavelength bands.

Specific examples of the four different wavelength bands will be shown.

In one example, in addition to the blue, green and red color filtersdescribed in Embodiment 2, the configuration further includes a nearinfrared light filter that substantially blocks visible light includingblue, green and red and transmits therethrough near infrared light.Thus, it is possible to realize an imaging apparatus for day and nightuse or an imaging apparatus for biometric authentication. With such animaging apparatus, when obtaining an image of near infrared light, it ispreferred to provide a light source having spectral radiationcharacteristics including the band of near infrared light.

In another example, in addition to the blue, green and red color filtersdescribed in Embodiment 2, the configuration further includes a nearultraviolet light filter that substantially blocks visible lightincluding blue, green and red and transmits therethrough nearultraviolet light. Thus, it is possible to realize an imaging apparatusfor visualizing conditions of the skin such as blotches due to nearultraviolet rays. With such an imaging apparatus, when obtaining animage of near ultraviolet light, it is preferred to provide a lightsource having spectral radiation characteristics including the band ofnear ultraviolet light.

In another example, in addition to the blue, green and red color filtersdescribed in Embodiment 2, the configuration further includes a filterthat transmits therethrough only a wavelength band of a narrower bandwidth than the band widths of the spectral transmittance characteristicsof the blue, green and red color filters. Thus, it is possible torealize an imaging apparatus for endoscope or capsule endoscopeapplications with which it is possible to observe lesions with a narrowband. The narrow band may or may not be included in the band of any ofthe blue, green and red color filters. With such an imaging apparatus,it is preferred to provide one type of a light source having spectralradiation characteristics including blue, green and red and the narrowband, or a plurality of types of light sources having spectral radiationcharacteristics corresponding respectively to the bands of blue, greenand red and the narrow band. The light source may include a white lightsource and a light source having spectral radiation characteristicsincluding the narrow band.

In the present embodiment, the pixel value is missing for every otherpixel in the x direction and in the y direction. Therefore, the pixelvalue of the pixel for which it is missing may be generated byinterpolation with pixel values of pixels adjacent thereto in the xdirection and in the y direction.

Two of the four areas obtained by four-fold division that oppose eachother with the optical axis interposed therebetween may be color filtersof the same green color. With such a configuration, the number of greenpixels increases, and it is therefore possible to improve the resolutionof the green image component.

Embodiment 4

Embodiment 4 is different from Embodiment 1 in that the first opticalarea D1 and the second optical area D2 are each arranged in two separateparts with the optical axis interposed therebetween, and that thearrayed optical device is switched from a lenticular to a microlens.Herein, what is substantially the same as Embodiment 1 will not bedescribed in detail.

FIG. 11( a) is a front view of the optical device L1 as seen from theobject side, and the optical areas D1 and D2 are each arranged in twoseparate parts opposing each other in an axial symmetry direction withthe optical axis V being the center so that the centroid thereof is theoptical axis position. FIG. 11( b) is a diagram showing the positionalrelationship between the arrayed optical device N and pixels on theimaging device N. In Embodiment 4, light beams having passed through theoptical area D1 arrive at odd-numbered row/odd-numbered column positionsand at even-numbered row/even-numbered column positions, and thereforethe odd-numbered row/odd-numbered column positions and the even-numberedrow/even-numbered column positions are added together to generate animage corresponding to the first wavelength band. Light beams havingpassed through the optical area D2 arrive at even-numberedrow/odd-numbered column positions and odd-numbered row/even-numberedcolumn positions, and therefore the even-numbered row/odd-numberedcolumn positions and the odd-numbered row/even-numbered column positionsare added together to generate an image corresponding to the secondwavelength band.

In Embodiment 1, the first optical area D1 and the second optical areaD2 are areas obtained by two-fold division of the optical device L1 inthe up-down direction in a plane vertical to the optical axis.Therefore, the spot centroids on the image plane of light having passedthrough different optical areas may vary depending on the objectdistance, thereby causing parallax.

FIG. 12 shows ray diagrams for different object distances in Embodiment1, and diagrams illustrating point images and changes in centroidsthereof. FIGS. 12( a 1), (b 1) and (c 1) show ray diagrams for differentobject distances. FIG. 12( a 1) is a ray diagram for a case where theobject point O is at the greatest distance from the optical system, FIG.12( c 1) is for a case where the object point O is at the leastdistance, and FIG. 12( b 1) is for a case where the object point O is ata distance between that of (a1) and that of (c1). The same elements asthose of FIG. 1 are denoted by the same reference signs. FIGS. 12( a 2)and (a 3), (b 2) and (b 3), and (c 2) and (c 3) show the point images(shown as semicircles) that are imaged through lenticulars and thecentroids thereof (shown as black dots), corresponding to the objectdistances of (a1), (b1) and (c1) of FIG. 12, respectively.

The point images are shown schematically as images obtained byinterpolating the image information (a2, b2, c2) extracted for eachodd-numbered column and the pixel information (a3, b3, c3) extracted foreach even-numbered column for pixel values that are missing for everyother pixel in the y direction. As the obtained image is divided intothe odd-numbered column image and the even-numbered column image asshown in the figure, the point images of the images are two semicircularshapes obtained by dividing a single circle in two. The spot diameterincreases as the object point O comes closer. Therefore, theinter-centroid distance d between the point images of the imagesincreases as the object comes closer. The inter-centroid distance d isnot desirable because it results in a parallax.

On the other hand, in Embodiment 4, the optical areas D1 and D2 arearranged to be separated from each other in an axial symmetry directionabout the optical axis so that the centroid thereof is the optical axisposition. Thus, the centroids of point images formed by light havingpassed through the optical areas D1 and D2 are also present at theoptical axis position. Therefore, the inter-centroid distance d betweenpoint images does not vary even when the object distance varies.

FIG. 13 shows diagrams illustrating point images and centroids thereoffor different object distances. In FIG. 13, (a1) and (a2), (b1) and(b2), and (c1) and (c2) show the point images (shown in semicircles)that are imaged through lenticulars and the centroids thereof (blackdots), corresponding to the object distances of (a1), (b1) and (c1) ofFIG. 12, respectively.

The point images schematically show image information (a1, b1, c1)obtained by adding together the odd-numbered row/odd-numbered columnpositions and the even-numbered row/even-numbered column positions, andimage information (a2, b2, c2) obtained by adding together theeven-numbered row/odd-numbered column positions and the odd-numberedrow/even-numbered column positions. As shown in the figure, inEmbodiment 4, when the obtained image is divided into an image obtainedby adding together the odd-numbered row/odd-numbered column positionsand the even-numbered row/even-numbered column positions and an imageobtained by adding together the even-numbered row/odd-numbered columnpositions and the odd-numbered row/even-numbered column positions, thepoint images of the images are fan shapes opposing each other in anaxial symmetry direction about the optical axis. Since the centroids ofthese point image coincide with each other, the inter-centroid distanced between the point images of the images does not vary even when theobject distance varies.

Thus, in Embodiment 4, as the optical areas D1 and D2 are each arrangedin separate parts opposing each other in an axial symmetry directionabout the optical axis so that the centroid thereof is the optical axisposition, it is possible to ensure that a parallax does not occurbetween obtained images even when the object distance varies.

Embodiment 5

Embodiment 5 is a configuration having two optical areas D1 and D2 as inEmbodiment 1, and further assumes that the lens L2 is a lens with axialchromatic aberration. With such a configuration, two areas withdifferent levels of optical power are provided in a plane vertical tothe optical axis in the vicinity of the stop so that the focus positionsof light beams having passed through the optical areas D1 and D2 aresubstantially equal to each other. The embodiment is different fromEmbodiment 1 in this regard. Herein, what is substantially the same asEmbodiment 1 will not be described in detail.

In the present embodiment, one of the two areas with different levels ofoptical power transmits therethrough light that passes through the firstoptical area D1. The other area transmits therethrough light that passesthrough the second optical area D2. The optical areas D1 and D2 and thetwo areas with different levels of optical power may be formed on thesame device or formed on different devices.

An imaging apparatus of the present embodiment will now be described indetail.

FIG. 14( a) is a diagram schematically showing a ray diagram inEmbodiment 1 in a case where the lens L2 is a lens that has axialchromatic aberration due to the wavelength dispersion characteristics ofthe refractive index as does a single lens. In FIG. 14( a), a filterthat transmits therethrough light of the first wavelength band is formedin the first optical area D1, and a filter that transmits therethroughlight of the second wavelength band, relatively longer than the firstwavelength band, is formed in the second optical area D2. Since the lensL2 is a lens that has axial chromatic aberration due to the wavelengthdispersion characteristics of the refractive index, as does a singlelens, for example, light having a longer wavelength is focused fartheraway from the lens. Therefore, if the settings are such that light beamshaving passed through the optical area D1 are focused on the imagingsurface Ni as shown in FIG. 14( a), light beams having passed throughthe optical area D2 will not yet be focused on the imaging surface Ni.

FIG. 14( b) is a diagram schematically showing a ray diagram for animaging apparatus of Embodiment 5. In FIG. 14( b), as compared with theconfiguration of FIG. 14( a), a lens surface with such optical powerthat light beams of the wavelength band of second spectral transmittancecharacteristics will focus on the imaging surface is formed in thesecond optical area D2 of the optical device L1. Therefore, light beamshaving passed through the first optical area D1 and light beams havingpassed through the second optical area D2 are both focused on theimaging surface Ni. Thus, according to the present embodiment, as thefirst optical area D1 and the second optical area D2 have differentlevels of optical power, the focus position of light passing through thefirst optical area D1 and the focus position of light passing throughthe second optical area D2 are brought closer to each other, as comparedwith a case where the first optical area D1 and the second optical areaD2 have an equal level of optical power. In FIG. 14( b), the opticalaxis V′ of the optical on one side of the optical area D2 of the opticaldevice L1 that is closer to the stop S has eccentricity as opposed tothe optical axis V of the lens optical system, but since the opticalpower is very small as compared with the optical power of the lens L2,there is little deterioration of imaging performance.

FIGS. 15( a) and (b) are perspective views of the optical device L1shown in FIG. 14( b). In either configuration, a filter having firstspectral transmittance characteristics is formed on the first opticalarea D1, and a filter having second spectral transmittancecharacteristics is formed on the second optical area D2, which is thelens surface. In the configuration of FIG. 15( a), the lens surface isformed across the entire areas obtained by dividing the optical deviceL1 in two. Therefore, there is a step between the first optical area,which is a plane, and the second optical area D2, which is a lenssurface. Since light beams having passed through such a step becomeunnecessary light, the stop S preferably has a configuration in which alight-blocking area is provided as shown in FIGS. 16( a) and (b). Withthe configuration of FIG. 15( b), a lens surface is formed in a portionof an area obtained by dividing the optical device L1 in two, to obtainthe optical area D2. This configuration requires a configuration where alight-blocking area is provided as shown in FIG. 16( c) so as tocorrespond to the optical areas D1 and D2.

FIGS. 17( a) and (b) are diagrams showing other embodiments ofEmbodiment 5. While the optical axis V′ of the surface on one side ofthe optical area D2 of the optical device L1 that is closer to the stopS is different from the optical axis V of the lens optical system inFIG. 14( b), the optical axis of the surface on one side of the opticalarea D2 of the optical device L1 that is closer to the stop S is thesame as the optical axis of the lens L2 in FIG. 17( a). FIG. 18 is aperspective view of the optical device L1 shown in FIG. 17( a). Withsuch a configuration, the eccentricity of the optical axis of the lenssurface of the optical area D2 of the optical device L1 is eliminated,and it is possible to eliminate the deterioration of imaging performancedue to eccentricity.

FIG. 17( b) is an example in which a separate lens is provided on theoptical device L1, as opposed to FIG. 17( a). In FIG. 17( b), theoptical device L1 on which filters of different spectral transmittancecharacteristics are formed is arranged on the object side in thevicinity of the stop, and an optical device L1′ is arranged on theobject side in the vicinity of the stop. Each of the optical devices L1and L1′ has the first optical area D1 and the second optical area D2.The second optical area D2 of the optical device L1′ has a lens surface.As described above, the element forming a filter and the element forminga lens may be separate from each other. The positions of L1 and L1′ maybe switched around with respect to the stop.

Thus, in Embodiment 5, even when the lens L2 is a lens, such as a singlelens, whose axial chromatic aberration is not corrected, the axialchromatic aberration can be reduced by providing two areas havingdifferent levels of optical power from each other in a plane vertical tothe optical axis.

Embodiment 6

Embodiment 6 is a configuration having three optical areas D1, D2 and D3as in Embodiment 2, and further assumes that the lens L2 is a lens withaxial chromatic aberration. With such a configuration, three areas withdifferent levels of optical power are provided in a plane vertical tothe optical axis in the vicinity of the stop so that the focus positionsof light beams having passed through the optical areas D1 and D2 aresubstantially equal to each other. The embodiment is different fromEmbodiment 5 in this regard. Herein, what is substantially the same asEmbodiment 5 will not be described in detail.

FIGS. 19( a), (b) and (c) are perspective views showing the opticaldevice L1 of Embodiment 6 where the optical area is divided in three.

The stop S has configurations shown in FIGS. 20( a), (b) and (c),similar to Embodiment 5.

Thus, in Embodiment 6, even if a lens, such as a single lens, whoseaxial chromatic aberration is not corrected is used, it is possible toreduce the axial chromatic aberration by providing three areas havingdifferent levels of optical power in a plane vertical to the opticalaxis.

Embodiment 7

Embodiment 7 is a configuration having four optical areas D1, D2, D3 andD4 as in Embodiment 3, and further assumes that the lens L2 is a lenswith axial chromatic aberration. With such a configuration, four areaswith different levels of optical power are provided in a plane verticalto the optical axis in the vicinity of the stop so that the focuspositions of light beams having passed through the optical areas D1 andD2 are substantially equal to each other. The embodiment is differentfrom Embodiment 5 in this regard. Herein, what is substantially the sameas Embodiment 5 will not be described in detail.

FIGS. 21( a), (b) and (c) are perspective views showing the opticaldevice L1 of Embodiment 7 where the optical area is divided in four.

The stop S has configurations shown in FIGS. 22( a), (b) and (c),similar to Embodiment 5.

Thus, in Embodiment 7, even if a lens, such as a single lens, whoseaxial chromatic aberration is not corrected is used, it is possible toreduce the axial chromatic aberration by providing four areas havingdifferent levels of optical power in a plane vertical to the opticalaxis.

Embodiment 8

Embodiment 8 is different from Embodiments 1-7 in that a lenticular lensor a microlens array is formed on the imaging surface. Herein, what issubstantially the same as Embodiments 1-7 will not be described indetail.

FIGS. 23( a) and (b) are enlarged views of the arrayed optical device Kand the imaging device N. In the present embodiment, a lenticular lens(or a microlens array) Md is formed on the imaging surface Ni of theimaging device N. The pixels P are arranged in a matrix pattern, as inEmbodiment 1, etc., on the imaging surface Ni. A single lenticular lensoptical element or a single microlens corresponds to a plurality ofpixels P. Also in the present embodiment, as in Embodiments 1-7, lightbeams having passed through different areas of the optical device L1 canbe guided to different pixels. FIG. 23( b) is a diagram showing avariation of the present embodiment. In the configuration shown in FIG.23( b), the microlenses Ms are formed on the imaging surface Ni so as tocover the pixels P, and the arrayed optical device is layered on thesurface of the microlenses Ms. With the configuration shown in FIG. 23(b), it is possible to increase the light-condensing efficiency ascompared with that of the configuration of FIG. 23( a).

When the arrayed optical device is separate from the imaging device asin Embodiments 1-7, the alignment between the arrayed optical device andthe imaging device is difficult. However, with a configuration where thearrayed optical device K is formed on the imaging device as inEmbodiment 8, the alignment can be done in the wafer process, therebymaking the alignment easier and improving the alignment precision.

Other Embodiments

While Embodiments 1-8 are directed to configurations where the opticalarea is divided in two, three, or four, the number of division may bemore.

While the lens L2 is a single lens, it may be a plurality of groups oflenses or a plurality of lenses.

While the optical area is arranged on one surface of the optical deviceL1 that is closer to the object, the optical area may be arranged on onesurface of the optical device L1 that is closer to the image. In thiscase, it is preferred that the optical device L1 is arranged on theobject side with respect to the position of the stop as it is thencloser to the stop.

While the optical device L1 is arranged on the image side with respectto the position of the stop, it may be arranged on the object side withrespect to the position of the stop. In this case, it is preferred thatthe optical area is arranged on the image side of the optical device L1as it is then closer to the stop.

While the lens surface provided on the element, which is different fromthe optical device L1 or the optical device L1, is arranged on theobject-side surface of the element in Embodiments 4, 5 and 6, it may bearranged on the image-side surface of the element.

While color filters arranged in different areas are arranged so thatthere is only one in the optical axis direction in Embodiments 1-8, aplurality of color filters may be layered on one another. For example, adielectric multi-layer film filter and an absorption-type filter havingdifferent spectral transmittance characteristics may be layeredtogether, or a dielectric multi-layer film may be formed on theabsorption-type filter.

In Embodiments 1-8, an image-side non-telecentric optical system may beused, or an image-side telecentric optical system may be used. Many ofthe lenses used in imaging devices such as cameras use a non-telecentricoptical system on the image side. Where an image-side non-telecentricoptical system is used for the lens optical system L of an embodiment ofthe present invention, the primary light beam is incident slantly on thearrayed optical device K if the angle of view changes. FIG. 24( a) is anenlarged view showing the vicinity the imaging section outside theoptical axis. FIG. 24( a) shows only the light beams, of all the lightpassing through the arrayed optical device K, that pass through oneoptical area. As shown in FIG. 24( a), where the lens optical system Lis an image-side non-telecentric optical system, light is likely to leakto adjacent pixels, thereby causing crosstalk. However, by offsettingthe arrayed optical device by A with respect to the pixel arrangement asshown in FIG. 24( b), it is possible to reduce the crosstalk and tosuppress deterioration in color purity. Since the angle of incidencevaries depending on the image height, the amount of offset Δ may be setin accordance with the angle of incidence of the light beam on theimaging surface.

An image-side telecentric optical system may be used for the lensoptical system L of an embodiment of the present invention. With animage-side telecentric optical system, the primary light beam isincident on the arrayed optical device K with a value close to 0 degreeeven if the angle of view changes, and it is therefore possible toreduce the crosstalk across the entire imaging area.

While the arrayed optical device K is a microlens array in Embodiments3, 4 and 7 of the present invention, each microlens optical element hasa shape that is rotationally symmetric with respect to the optical axisof the microlens. As a method for manufacturing a microlens, there is amethod in which a resist is patterned into a rectangular shape, and thecurved surface of the lens is formed by heat treatment. A perspectiveview of such microlenses is as shown in FIG. 25( a 1). The contour linesof the microlens of FIG. 25( a 1) are as shown in FIG. 25( a 2), and theradius of curvature in a vertical/horizontal direction and that in adiagonal direction are different from each other. FIG. 25( a 3) showsthe results of light beam tracking simulation in a case where themicrolens shown in FIGS. 25( a 1) and (a 2) is used as the arrayedoptical device of the present invention. FIG. 25( a 3) only shows lightbeams, of all the light passing through the arrayed optical device K,that pass through one optical area. With such a microlens that is notrotationally asymmetric, light leaks to adjacent pixels, causingcrosstalk. On the other hand, a perspective view of microlenses having arotationally symmetric shape is as shown in FIG. 25( b 1). The contourlines of the microlens of FIG. 25( b 1) are as shown in FIG. 25( b 2),and the radius of curvature in a vertical/horizontal direction and thatin a diagonal direciton are equal to each other. Such microlenses havinga rotationally symmetric shape can be formed by a thermal imprint or UVimprint method. FIG. 25( b 3) shows the results of light beam trackingsimulation in a case where the microlens shown in FIGS. 25( b 1) and (b2) is used as the arrayed optical device of the present invention. FIG.25( b 3) only shows light beams, of all the light passing through thearrayed optical device K, that pass through one optical area. It can bethat there is no such crosstalk as that shown in FIG. 25( a 3). Thus, bymaking each microlens optical element in a rotationally symmetric shape,it is possible to reduce the crosstalk, thereby suppressingdeterioration in color purity.

While Embodiments 5, 6 and 7 show examples in which a light-blockingarea is provided in the stop at a position corresponding to the stepportions in order to prevent unnecessary light passing through steps,since light beams passing through the vicinity of boundaries betweendifferent areas may cause crosstalk as described above, such a stop asshown in FIG. 16, FIG. 20 and FIG. 22 may be provided in order toprevent crosstalk even if there is no step.

The imaging device used in Embodiments 1-8 may be either a monochromeimaging device or a color imaging device. For example, when a colorimaging device is used, the width of the wavelength band of lightpassing through at least area of the optical device L1 may be narrowerthan the width of the wavelength band of the color filter on the pixelat which the light beam having passed through the area arrives. Since acolor imaging device is used for the imaging device, it is not necessaryto provide a color filter in areas other than the at least one area ofthe optical device L1. With such a configuration, it is possible toobtain image information of a narrow band and to attenuate the componentof the wavelength band caused by crosstalk because of the effect of thespectral transmittance characteristics of the color imaging device.Since it is not necessary to provide a color filter on the opticaldevice L1 except for the at least one area, it is possible to reduce thecost.

Embodiments 1-8 are imaging apparatuses having the signal processingsection C. An imaging apparatus of the present invention may not includesuch a signal processing section. In such a case, processes performed bythe signal processing section C may be performed by using a PC, or thelike, external to the imaging apparatus. That is, the present inventionmay also be implemented by a system including an imaging apparatushaving the lens optical system L, the arrayed optical device K and theimaging device N, and an external signal processing device.

INDUSTRIAL APPLICABILITY

An imaging apparatus of the present invention is useful as an imagingapparatus such as a digital still camera or a digital video camera. Itis also applicable to cameras for obtaining spectral images, such ason-vehicle cameras, security cameras, medical applications, e.g.,endoscopes and capsule endoscopes, biometric authenticationapplications, microscopes, and astronomical telescopes.

REFERENCE SIGNS LIST

A Imaging apparatus

L Lens optical system

L1, L1′ Optical device

L2 Lens

D1, D2, D3, D4 Optical area

S Stop

K Arrayed optical device

N Imaging device

Ni Imaging surface

Ms, Md Microlens on imaging device

M1 Optical element of arrayed optical device (lenticular)

M2 Optical element of arrayed optical device (microlens)

P1, P2, P3, P4, P Pixel on imaging device

C Signal processing section

1. An imaging apparatus comprising: a lens optical system including alens and a stop; an imaging device including at least a plurality offirst pixels and a plurality of second pixels on which light havingpassed through the lens optical system is incident; and an arrayedoptical device arranged between the lens optical system and the imagingdevice, wherein: the lens optical system further includes a plurality ofoptical areas in a plane vertical to an optical axis; the plurality ofoptical areas include a first optical area that transmits therethroughlight of a first wavelength band, and a second optical area thattransmits therethrough light of a second wavelength band different fromthe first wavelength band; and the arrayed optical device makes lighthaving passed through the first optical area incident on the pluralityof first pixels and light having passed through the second optical areaincident on the plurality of second pixels.
 2. The imaging apparatusaccording to claim 1, wherein the plurality of optical areas arearranged in the vicinity of the stop.
 3. The imaging apparatus accordingto claim 1, wherein: the plurality of optical areas of the lens opticalsystem further include at least a third optical area other than thefirst and second optical areas; the third optical area transmitstherethrough light of a third wavelength band different from the firstwavelength band and the second wavelength band; and the arrayed opticaldevice makes light having passed through the third optical area on athird pixel other than the plurality of first and second pixels.
 4. Theimaging apparatus according to claim 3, wherein: the plurality ofoptical areas of the lens optical system further include a fourthoptical area other than the first, second and third optical areas, andthe fourth optical area transmits therethrough light of a fourthwavelength band different from the first, second and third wavelengthbands; and the arrayed optical device makes light having passed throughthe fourth optical area incident on a fourth pixel other than theplurality of first, second and third pixels.
 5. The imaging apparatusaccording to claim 1, wherein the first and second optical areas of thelens optical system is each formed by a plurality of optical areasseparated from each other with the optical axis interposed therebetween.6. The imaging apparatus according to claim 1, wherein the light of thefirst wavelength band is near infrared light, and the light of thesecond wavelength band is visible light.
 7. The imaging apparatusaccording to claim 1, wherein the light of the first wavelength band isnear ultraviolet light, and the light of the second wavelength band isvisible light.
 8. The imaging apparatus according to claim 1, wherein awidth of the second wavelength band is narrower than a width of thefirst wavelength band.
 9. The imaging apparatus according to claim 1,wherein the first optical area and the second optical area are opticalareas separated from each other in a plane vertical to the optical axisof the lens optical system with the optical axis being a center of aboundary.
 10. The imaging apparatus according to claim 14, wherein: thefirst optical area and the second optical area have different levels ofoptical power; a focus position of light passing through the firstoptical area and a focus position of light passing through the secondoptical area are closer to each other as compared with a case where thefirst optical area and the second optical area have an equal level ofoptical power.
 11. The imaging apparatus according to claim 1, wherein:the lens optical system is an image-side non-telecentric optical system;and an arrangement of the arrayed optical device is offset with respectto an arrangement of pixels of the imaging device outside the opticalaxis of the lens optical system.
 12. The imaging apparatus according toclaim 1, wherein the lens optical system is an image-side telecentricoptical system.
 13. The imaging apparatus according to claim 1, whereinthe arrayed optical device is a lenticular lens.
 14. The imagingapparatus according to claim 1, wherein the arrayed optical device is amicrolens array.
 15. The imaging apparatus according to claim 14,wherein a shape of each optical element of the microlens array is arotationally symmetric shape.
 16. The imaging apparatus according toclaim 1, wherein the arrayed optical device is formed on the imagingdevice.
 17. The imaging apparatus according to claim 16, furthercomprising: a microlens provided between the arrayed optical device andthe imaging device, wherein the arrayed optical device is formed on theimaging device with the microlens interposed therebetween.
 18. Theimaging apparatus according to claim 1, further comprising alight-blocking area at a position corresponding to a boundary portionbetween the first optical area and the second optical area.
 19. Theimaging apparatus according to claim 1, wherein: the imaging device is acolor imaging device with a color filter formed on each pixel; and awidth of a wavelength band of at least one optical area of the pluralityof optical areas is narrower than a width of a wavelength band of acolor filter on the color imaging device at which a light beam havingpassed through the at least one optical area arrives.
 20. The imagingapparatus according to claim 1, further comprising: a signal processingsection, wherein the signal processing section generates first imageinformation corresponding to the first wavelength band from pixel valuesobtained from the plurality of first pixels, and generates second imageinformation corresponding to the second wavelength band from pixelvalues obtained from the plurality of second pixels.
 21. An imagingsystem comprising: the imaging apparatus according to any one of claims1 to 19; and a signal processing device for generating first imageinformation corresponding to the first wavelength band from pixel valuesobtained from the plurality of first pixels of the imaging apparatus,and generating second image information corresponding to the secondwavelength band from pixel values obtained from the plurality of secondpixels.
 22. An imaging method using an imaging apparatus comprising: alens optical system including at least a first optical area thattransmits therethrough light of a first wavelength band, and a secondoptical area that transmits therethrough light of a second wavelengthband different from the first wavelength band; an imaging deviceincluding at least a plurality of first pixels and a plurality of secondpixels on which light having passed through the lens optical system isincident; and an arrayed optical device arranged between the lensoptical system and the imaging device, wherein: the arrayed opticaldevice makes light having passed through the first optical area incidenton the plurality of first pixels and light having passed through thesecond optical area incident on the plurality of second pixels; and afirst image corresponding to the first wavelength band is generated frompixel values obtained from the plurality of first pixels, and secondimage information corresponding to the second wavelength band isgenerated from pixel values obtained from the plurality of secondpixels.